Catalyst for selectively catalytically oxidizing hydrogen sulfide, catalyst for burning tail-gas, and process for deeply catalytically oxidizing hydrogen sulfide to element sulfur

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A catalyst for selectively oxidizing hydrogen sulfide to element sulfur, catalyst for burning tail-gas, and process for deeply catalytically oxidizing hydrogen sulfide to sulfur are disclosed. The catalyst for selectively oxidizing hydrogen sulfide to element sulfur is prepared by: 10-34% of iron trioxide and 60-84% of anatase titanium dioxide, and the balance being are auxiliary agents. Also a catalyst for burning tail-gas is prepared by: 48-78% of iron trioxide and 18-48% of anatase titanium dioxide, and the balance being auxiliary agents. The catalyst of the present invention has high selectivity and high sulfur recovery rate. An isothermal reactor and an adiabatic reactor of the present invention are connected in series and are filled with the above two catalysts for reactions, thus reducing total sulfur in the vented gas while having a high sulfur yield and conversion rate.

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Description
CROSS REFERENCE OF RELATED APPLICATION

This is a U.S. National Stage under 35 U.S.C 371 of the International Application PCT/CN2015/093756, filed Nov. 4, 2015, which claims priority under 35 U.S.C. 119(a-d) to CN 2014106178633, filed Nov. 5, 2014.

BACKGROUND OF THE PRESENT INVENTION Field of Invention

The present invention relates to a catalyst for selectively catalytically oxidizing hydrogen sulfide, catalyst for burning tail-gas and process for deeply catalytically oxidizing hydrogen sulfide to element sulfur, belonging to catalyst application field.

Description of Related Arts

The Claus process (H2S≥30%) and direct oxidation method (H2S≤20%) are adopted for recovery of sulfur from acid gas according to different H2S concentration. modified Claus process adopts acid gas burner (1200-1300° C.)—two steps or three steps Claus catalytic conversion (200-300° C.)—Claus tail-gas treatment unit (reduction and absorption method)—tail-gas burner (750-1300° C.). The advantages of the modified Claus process are developed techniques, strong dealing capability and a sulfur recovery rate of 95-97%. The investment and operating cost of the tail-gas dealing unit is high. The overall investment on a sulfur recovery unit with a dealing capability of 50000 tons of sulfur/year is over RMB140 million of which the tail-gas treatment unit accounts for RMB 80 million. The flue gas consumption of the tail-gas burner is over RMB120 million/year. The cost of the sulfur is RMB 1500/ton while the market price of the sulfur is RMB600-1000/ton. When the H2S content is low (≤20%) the direct oxidation method is adopted. The detailed procedures are as below: adopt CLINSULF-DO produced by © The Linde Group; blend and preheat the acid gas and the oxygen-containing gas—inner-cooling pipe reactor (top adiabatic section and the bottom isothermal section)—condensate separation—tail-gas burner; use CRS-31 catalyst Prandtl French company. The features of the CLINSULF-DO are short process, easy operation, long-life catalyst, sulfur recovery rate ≤90%, low selectivity and the tail-gas may also contains H2S and SO2. The CLINSULF-DO is not transferred any long. Selextox process adopts four steps reactor and the detailed method is as below: preheat the oxygen-containing acid gas mixture—catalytic oxidation step—two steps Claus process—catalytic burning step—chimney emission; adopt selection catalyst. The overall sulfur recovery rate is ≤90%. When the acid gas H2S is ≥5%, cyclic process is needed, that is the tail-gas cycle return to the oxidation step. Super/Euro-claus from the ©Hofung Technology is a Claus tail-gas treatment method which supports the regular Claus sulfur recovery process; the detailed process is as below: tail-gas from the two steps Claus process—hydrotransformation—Super/Euroclaus—condensate separation—tail-gas burning; the sulfur recovery rate of the catalytic oxidation step is ≤85%. The tail-gas of the oxidation processes has an unacceptable sulfur content (total sulfur ≥960 mg/m3, 1996 standard PRC).

The inventor introduced a process and a catalyst for selectively oxidizing low-H2S-concentration-containing acid gas (H2S≤3.0%) in patent CN200810157750. For all the embodiments, H2S is ≤2% and an adiabatic reactor is adopted, at the outlet of which H2S and SO2 exist in the same time. H2S: 20-60 mg/m3, SO2: 100-200 mg/m3. Although the total sulfur content is reduced, the H2S is far exceeding the emission standard (H2S≤5 mg/m3). So re-treating is needed. Otherwise, when the H2S concentration is high, the activity of the H2S and the sulfur recovery is unsatisfying. The catalytically oxidizing catalysts have the following features in common: adopting adiabatic reactor, simple structure, high conversion rate, narrow applications, low concentration acid gas only (non-cycling, H2S≤3%), the sulfur recovery rate ≯90%; furthermore, the catalyst selectivity is inefficient and the tail-gas at the outlet may also contains H2S and SO2 in the same time, which need to be re-treated. Generally, the tail-gas is able to be treated with thermal incineration and catalytic incineration. The thermal incineration is to add flue gas in the tail-gas of the thermal incinerator to convert the H2S to low-toxic SO2 under high temperature of 700-800° C. with little sulfur recovery effects. The catalytic incineration (not applied in PRC) is to adopt the tail-gas burning catalyst to convert the H2S under the temperature of 300-400° C. The sulfur recovery rate is ≤30%. Large amount of H2S-containing gas is emitted to the atmosphere, which pollute the environment and waste the sulfur resource. In PRC, the thermal incineration is widely used, which has large flue gas consumption. According to the data of a sulfur recovery device which adopts reduction and absorption method and with a capability of 80000 tons of sulfur/year, the flue gas consumption is amount to 2200 tons and over RMB100 million. Currently, the requirement for environment protection is imperative, the total sulfur (SO2) emission target is down from 960 mg/m3 to 400 mg/m3 in the Emission standard of air pollutants issued in 2014 (PRC). So the need for a new sulfur recovery technology which is able to replace the Claus process is imperative. The key is to develop a selectively oxidizing catalyst with high sulfur recovery rate and a tail-gas burning catalyst with high conversion rate and high sulfur recovery rate, which is able to save energy, cut the emission, clean the environment, transfer the pollutants to the resource to the maximum extend, high profit yield and promote a healthy recycle in environment protection field.

In the oxidation reaction of H2S, two different reactions exists:
H2S+½O2—S+H2O ΔH(273K)=−222 KJ/mol  (1)
H2S+3/2O2—SO2+H2O ΔH(273K)=−519 KJ/mol  (2)

The following conclusion is able to be drawn: the oxidation reaction of the H2S is strong exothermic reaction; under adiabatic condition, the reaction (1) has a temperature rise of 60° C. while 1% H2S oxidizing to element sulfur. Low temperature is favorable for the oxidation reaction. Without the catalyst, when the temperature reach 260° C. reaction (2) started. The reaction (2) is unfavorable reaction which should be avoided. So, the research hot topic is how to promote reaction (1), suppress reaction (2) develop catalyst with high activity and selectivity and find out suitable process.

SUMMARY OF THE PRESENT INVENTION

An object of the present invention is to provide a catalyst for selectively catalytically oxidizing hydrogen sulfide, which has high selectivity and high sulfur recovery rate.

Another object of the present invention is to provide a catalyst for burning tail-gas and provide a process for deeply catalytically oxidizing hydrogen sulfide to element sulfur, which is easy to operate and control.

The catalyst for selectively catalytically oxidizing Hydrogen sulfide, comprising components of a mass percent of: 10-34% of iron trioxide, 60-84% of anatase titanium dioxide and a balance which are auxiliary agents.

The catalyst for burning tail-gas, comprising components of a mass percent of: 48-78% of iron trioxide, 18-48% of anatase titanium dioxide and a balance which are auxiliary agents.

The catalyst for burning tail-gas, further comprises a mass percent of 0.4-0.8% of vanadium pentoxide.

The process for deeply catalytically oxidizing Hydrogen sulfide to element sulfur, wherein an isothermal reactor and adiabatic reactor are connected in series, which are filled with a catalyst for selectively catalytically oxidizing hydrogen sulfide and a catalyst for burning tail-gas respectively for reaction; wherein:

in the isothermal reactor the catalyst for selectively catalytically oxidizing Hydrogen sulfide is used under the following conditions:

temperature 150-300° C.,

space velocity 300-2000/h, 300-1000/h is preferred;

O2/H2S mole ratio 0.5-1.5, 0.5-1.0 is preferred;

in the adiabatic reactor, the catalyst for burning tail-gas is used under the following conditions:

temperature 180-350° C.,

space velocity 1000-2000/h,

O2/H2S mole ratio 1.0-3.0, 1.5-2.0 is preferred.

In the process, air is injected in a gas mixture at an entrance of the isothermal reactor according to the O2/H2S mole ratio required by the catalyst for selective oxidation and the gas mixture passes through a source gas; a sulfur recovery rate of an isothermal reaction is ≥95%; air is injected at an entrance of the adiabatic reactor according to the O2/H2S mole ratio required by the catalyst for burning tail-gas; in an adiabatic reaction a sulfur recovery rate is ≥90%, a conversion rate is ≥99%; in the vented-gas, SO2 is ≤400 mg/m3, H2S is ≤5 mg/m3.

The auxiliary agents in the present invention are regular auxiliary agents, such as water glass, aluminum sol, silica sol, dilute nitric acid, sesbania powder, carboxymethyl cellulose and etc. The raw material is able to be get from the market, which contains 85% of the ferric oxide, industrial-grade meta-titanic acid (80% is titanium dioxide), 2% of dilute nitric acid aqueous solution.

The catalyst for selectively catalytically oxidizing hydrogen sulfide and the catalyst for burning tail-gas are processed according to the following steps:

Take the iron oxide (if the catalyst for burning tail-gas contains vanadium pentoxide, ammonium metavanadate of the same measurement as vanadium pentoxide is added at the same time); add dilute nitric acid aqueous solution (volume is 12-15% of the mass of iron oxide); blend for 30 minutes; then add meta-titanic acid, add aluminum sol and silica sol at the same time (volume is 10% of the total mass of iron oxide and meta-titanic acid); mix the solution with the sesbania powder (the mass of the sesbania powder is measured as 1% of the total amount of iron oxide and meta-titanic acid) and knead in the kneader for 40 minutes; then squeeze out a column of semi-finished product of 4 mm in diameter by using a screw extruder; place the semi-finished product in an environment with a temperature of 25° C. for 24-hour natural drying; then place the semi-finished product in the oven to dry for 2 hours under 150° C.; finally place the dried semi-finished product in the muffle and roast for 2 hours under 450° C. to get the test sample.

The benefits of the present invention are as follow:

In the process of catalytically oxidizing hydrogen sulfide to element sulfur, the adoption of the selective oxidation catalyst of the present invention significantly improves the selectivity of the catalyst and get high sulfur recovery rate which is ≥95%. The total sulfur content in the vented-gas is reduced significantly and the vented-gas deep purification burden is eased. The tail-gas burning catalyst is set after the selective oxidation catalyst, which further recovers the sulfur and the sulfur recovery rate is ≥90%, the residue of the hydrogen sulfide (≤10%) is completely converted to low-toxic sulfur dioxide. The high energy-consumption tail-gas burner is no longer needed, which cut the energy consumption and operation cost significantly. The method is simple and easy to control and operate. The present invention adopts a combination method of two different catalysts in the isothermal reactor and adiabatic reactor respectively, which extremely extends the H2S concentration range of the acid gas treatment. Self-heat balance is achieved within the system. The operation cost is less then 10% of the Claus process and the investment cost is 20% of the Claus process with the similar dealing capability. The present invention is able to replace the conventional Claus process and achieve the goal in one step. Realize the direct emission of the vented-gas without the burner while ensure a high sulfur recovery rate. The present invention fulfills the requirement of Emission standard of air pollutants issued in 2014 (PRC) and greatly benefits the environment and economy.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a flow chart of a method of the present invention

Element number: 1. air filter; 2. air compressor; 3. pressure regulator; 4-1. first water-vapor separator; 4-2. second water-vapor separator; 5. air flow meter; 6. acid gas storage tank; 7. acid gas filter; 8. entrance stop valve; 9. acid gas flow meter; 10. acid gas heat exchanger; 11. gas mixing valve; 12. mixing heat exchanger; 13. isothermal reactor; 14. adiabatic reactor; 15-1. first collector; 15-2. second collector; 16. modified activated carbon filter tank; 17. heat conduction oil tank; 18. heat conduction cycling pump.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Referring to the drawings, according to a preferred embodiment of the present invention is illustrated, wherein

The following instruments and condition are adopted for the catalyst activity evaluation in the embodiments.

CHT-02 small catalyst activity evaluation device (Beijing Wekindu Technology Co., Ltd);

TY-2000 integrated trace sulfur analyzer (Automation research branch of Southwest research & design institute of chemical industry);

3420A—gas chromatography analyzer (Beijing Maihak analytical instrument Co. Ltd.).

Note: Due to the H2S concentration of the acid gas of the source gas and the tail-gas of the reactor (≤100 mg/m3) differs greatly, different analysis methods are adopted. So, the thermal conductivity detector of the gas chromatography is adopted for the source gas; the flame photometric detector is adopted for the analysis of the tail-gas. Another gas line of the gas chromatography adopts 4A molecular sieves as the support for analysis of the oxygen content in the acid gas.

Embodiment 1-3

In the embodiment 1-3, the isothermal reactor adopts catalyst A, B, C for selectively catalytically oxidizing hydrogen sulfide respectively. The evaluation condition parameter of the catalyst activity is listed in chart 1. The activity evaluation data and catalyst composition is listed in chart 2.

Contrast 1

In the contrast 1, the isothermal reactor adopts conventional catalyst D. The evaluation condition parameter of the catalyst activity is listed in chart 1. The activity evaluation data and catalyst composition is listed in chart 2.

CHART 1 Evaluation condition of the activity of the selective oxidation catalyst Space velocity Acid gas flow Volume of the Granularity of the (based on the after air is injected catalyst sample mixed acid gas) in Air flow 8 ml 20-40 mesh 1500 h−1 200 ml/min 136 ml/min Acid gas after air Residual oxygen Water content of Source acid gas is injected in content in tail- Oxygen content in saturated water H2S % H2S % gas % air % vapor (40° C.) 11.75 8.45-8.65 0.14 21 5.8%

CHART 2 Activity evaluation data of the selective oxidation catalyst Composition A B C D Fe2O3: 10% Fe2O3: 24% Fe2O3: 34% Fe2O3: 5% TiO2: 84% TiO2: 70% TiO2: 60% TiO2: 75% Tail-gas Temperature H2S % SO2 % S % H2S % SO2 % S % H2S % SO2 % S % H2S % SO2 % S % 160° C. 0.4165 0 95.1 0.4165 0 95.1 0.4080 0 95.2 0.6201 0.4001 87.9 0.3995 0 95.3 0.4080 0 95.2 0.3910 0 95.4 0.6513 0.4012 87.6 200° C. 0 0.1700 98.0 0 0.2465 97.1 0 0.2310 97.2 0.2104 0.5691 91.9 0 0.2550 97.0 0 0.2550 97.0 0 0.2165 97.4 0.2204 0.4660 91.9 250° C. 0.0010 0.3390 96.0 0.0070 0.2883 96.6 0.0109 0.2676 96.7 0.3728 0.6372 88.2 0.0009 0.3221 96.2 0.0080 0.3137 96.3 0.0110 0.2760 96.6 0.3120 0.4956 90.4 300° C. 0.0015 0.3895 95.4 0.0091 0.3734 95.5 0.0254 0.3486 95.6 0.2023 0.6627 89.8 0.0014 0.3726 95.6 0.0089 0.3561 95.6 0.0161 0.3494 95.7 0.2013 0.6042 90.5

Embodiment 4-7

In the embodiment 4-7, the adiabatic reactor adopts tail-gas burning catalyst E, F, G, H. The evaluation condition parameter of the catalyst activity is listed in chart 3. The activity evaluation data and catalyst composition is listed in chart 4.

CHART 3 Evaluation condition of the activity of the tail-gas burning catalyst Space velocity Volume of the Granularity of the (based on the Acid gas flow after catalyst sample mixed acid gas) air is injected in Air flow 8 ml 20-40 mesh 1500 h−1 200 ml/min 136 ml/min Acid gas after air Residual oxygen Water content of Source acid gas is injected in content in tail- Oxygen content in saturated water H2S % H2S % gas % air % vapor (40° C.) 5.20-5.34 3.15-3.25 0.52 20 5.8%

CHART 4 Activity evaluation data of the tail-gas burning catalyst Composition E F Fe2O3: 48% Fe2O3: 48% G H TiO2: 48% TiO2: 48% Fe2O3: 60% Fe2O3: 78% V2O5: 0.4% V2O5: 0.8% TiO2: 26% TiO2: 18% Tail-gas Temperature H2S % SO2 % S % H2S % SO2 % S % H2S % SO2 % S % H2S % SO2 % S % 180° C. 0 0.2526 92.1 0. 0.2231 93.0 0 0.2353 94.1 0 0.1032 96.7 0 0.2401 92.5 0. 0.2064 93.5 0 0.2754 94.4 0 01008 96.8 250° C. 0 0.1504 95.3 0 0.1485 95.3 0 0.2433 92.3 0 0.1876 94.1 0 0.1440 95.5 0 0.1523 95.2 0 0.2305 92.7 0. 0.1794 94.3 300° C. 0.01 0.1823 93.7 0.0094 0.1586 94.7 0.0016 0.1978 93.7 0. 0.2643 91.7 800.0233 0.1704 93.9 0.0078 0.1608 94.7 0.0008 0.2105 93.3 0 0.2712 91.5 350° C. 0.0124 0.2311 92.3 0.0041 0.2853 90.9 0.0122 0.3023 90.1 0.0014 0.3132 90.1 0.0145 0.2115 92.9 0.0068 0.2794 91.0 0.0136 0.2984 90.2 0.0023 0.2983 90.6

Embodiment 8

The process for deeply catalytically oxidizing hydrogen sulfide to element sulfur of the present invention adopts an isothermal reactor and an adiabatic reactor connected in series, which are filled with the catalyst for selectively catalytically oxidizing hydrogen sulfide and the catalyst for burning tail-gas respectively for reaction.

As illustrated in FIG. 1, the air after being filtered by the air filter 1 passes through the air compressor 2, the pressure regulator 3, the first water-vapor separator 4-1, the air flow meter 5 and reaches the gas mixing valve 11; the acid gas from the acid gas storage tank 6 passes through the second water-vapor separator 4-2, the acid gas filter 7, the entrance stop valve 8, the acid gas flow meter 9, the acid gas heat exchanger 10 and reached the gas mixing valve 11 to blend with air. The mixed gas passed through the mixing heat exchanger 12, the isothermal reactor 13, the first collector 15, the adiabatic reactor 14; the second collector 15-2, and is emitted after being treated by the modified activated carbon filter tank 16; the heat conduction oil tank 17 is set between the mixing heat exchanger 12 and the isothermal reactor 13; the heat conduction cycling pump 18 recycle and utilize the heat. The acid gas enters the isothermal reactor after being filled with air; the isothermal reactor adopts the catalyst A for selectively catalytically oxidizing hydrogen sulfide; the method parameters are listed in Chart 1; the space velocity is 1500/h; the reaction temperature is 200° C.; the tail-gas composition and sulfur recovery rate are listed in Chart 2; the tail gas enters the adiabatic reactor after being filled with air; the adiabatic reactor adopts the catalyst E for burning tail-gas; the space velocity is 1000/h; O2/H2S mole ratio is 1.5; the reaction temperature is 250° C.; the sulfur recovery rate of the adiabatic reaction is 95.3%; the conversion rate is 99.5%; in the vented tail-gas, SO2 is 0.1504 mg/m3, H2S is 0.

Embodiment 9

The process for deeply catalytically oxidizing hydrogen sulfide to element sulfur of the present invention adopts an isothermal reactor and an adiabatic reactor connected in series, which are filled with the catalyst for selectively catalytically oxidizing hydrogen sulfide and the catalyst for burning tail-gas respectively for reaction. The method is explained in the embodiment 8. The acid gas enters the isothermal reactor after being filled with air; the isothermal reactor adopts the catalyst B for selectively catalytically oxidizing hydrogen sulfide; the method parameters are listed in the Chart 1; the space velocity is 1500/h; the reaction temperature is 250° C.; the composition of the tail-gas and the sulfur recovery rate are listed in the Chart 2; the tail-gas enters the adiabatic rector after being filled with air; the adiabatic reactor adopts the catalyst F for burning tail-gas; the space velocity is 2000/h; the O2/H2S mole ratio is 2.0; the reaction temperature is 300° C.; the sulfur recovery rate of the adiabatic reaction is 94.7%; the conversion rate is 99.8%; in the vented tail-gas, SO2 is 0.1608 mg/m3, H2S is 0.0094 mg/m3.

Claims

1. A catalyst for selectively catalytically oxidizing hydrogen sulfide, comprising components of a mass percent of: 13-34% of iron trioxide, 60-72% of anatase titanium dioxide and a balance which are auxiliary agents.

2. A catalyst for burning tail-gas, comprising components of a mass percent of: 48-78% of iron trioxide, 18-48% of anatase titanium dioxide and a balance which are auxiliary agents.

3. The catalyst for burning tail-gas, as recited in claim 2, further comprising a mass percent of 0.4-0.8% of vanadium pentoxide.

4. A method for deeply catalytically oxidizing hydrogen sulfide to element sulfur comprises the following steps:

adopting an isothermal reactor and an adiabatic reactor which are connected in series; and
filling the isothermal reactor and the adiabatic reactor with a catalyst for selectively catalytically oxidizing the hydrogen sulfide and a catalyst for burning tail-gas respectively for reaction, wherein
the catalyst for selectively catalytically oxidizing the hydrogen sulfide comprises components of a mass percent of: 10-34% of iron trioxide, 60-84% of anatase titanium dioxide and a balance which are auxiliary agents; and
the catalyst for burning the tail-gas comprises components of a mass percent of: 48-78% of iron trioxide, 18-48% of anatase titanium dioxide and a balance which are auxiliary agents.

5. The method for deeply catalytically oxidizing the hydrogen sulfide to the element sulfur, as recited in claim 4, comprising the catalyst for burning the tail-gas with a mass percent of 0.4-0.8% of vanadium pentoxide.

6. The method for deeply catalytically oxidizing the hydrogen sulfide to the element sulfur, as recited in claim 5, injecting air into a gas mixture at an entrance of the isothermal reactor according to a O2/H2S mole ratio required by the catalyst for selective oxidation and the gas mixture passes through a source gas; a sulfur recovery rate of an isothermal reaction is ≥95%; injecting air at an entrance of the adiabatic reactor according to a O2/H2S mole ratio required by the catalyst for burning tail-gas; in an adiabatic reaction a sulfur recovery rate is ≥90%, a conversion rate is ≥99%; in vented tail-gas, SO2 is ≤400 mg/m3, H2S is ≤5 mg/m3.

7. The method for deeply catalytically oxidizing the hydrogen sulfide to the element sulfphur, as recited in claim 4, using the catalyst for selectively catalytically oxidizing the hydrogen sulfide under following conditions: a temperature of 150-300° C., a space velocity of 300-2000/h, and an O2/H2S mole ratio of 0.5-1.5.

8. The method for deeply catalytically oxidizing the hydrogen sulfide to the element sulfur, as recited in claim 7, wherein the space velocity is between 300-1000/h, the O2/H2S mole ratio is between 0.5-1.0.

9. The method for deeply catalytically oxidizing the hydrogen sulfide to the element sulfur, as recited in claim 8, injecting air into a gas mixture at an entrance of the isothermal reactor according to the O2/H2S mole ratio required by the catalyst for selective oxidation and the gas mixture passes through a source gas; a sulfur recovery rate of an isothermal reaction is ≥95%; injecting air at an entrance of the adiabatic reactor according to a O2/H2S mole ratio required by the catalyst for burning tail-gas; in an adiabatic reaction a sulfur recovery rate is ≥90%, a conversion rate is ≥99%; in vented tail-gas, SO2 is ≤400 mg/m3, H2S is ≤5 mg/m3.

10. The method for deeply catalytically oxidizing the hydrogen sulfide to the element sulfur, as recited in claim 7, injecting air into a gas mixture at an entrance of the isothermal reactor according to the O2/H2S mole ratio required by the catalyst for selective oxidation and the gas mixture passes through a source gas; a sulfur recovery rate of an isothermal reaction is ≥95%; injecting air at an entrance of the adiabatic reactor according to a O2/H2S mole ratio required by the catalyst for burning tail-gas; in an adiabatic reaction a sulfur recovery rate is ≥90%, a conversion rate is ≥99%; in vented tail-gas, SO2 is ≤400 mg/m3, H2S is ≤5 mg/m3.

11. The method for deeply catalytically oxidizing the hydrogen sulfide to the element sulfphur, as recited in claim 4, using the catalyst for burning the tail-gas under following conditions: a temperature of 180-350° C., a space velocity of 1000-2000/h, an O2/H2S mole ratio of 1.0-3.0.

12. The method for deeply catalytically oxidizing the hydrogen sulfide to the element sulfphur, as recited in claim 11, wherein the O2/H2S mole ratio is between 1.5-2.0.

13. The method for deeply catalytically oxidizing the hydrogen sulfide to the element sulfur, as recited in claim 12, injecting air into a gas mixture at an entrance of the isothermal reactor according to a O2/H2S mole ratio required by the catalyst for selective oxidation and the gas mixture passes through a source gas; a sulfur recovery rate of an isothermal reaction is ≥95%; injecting air at an entrance of the adiabatic reactor according to the O2/H2S mole ratio required by the catalyst for burning tail-gas; in an adiabatic reaction a sulfur recovery rate is ≥90%, a conversion rate is ≥99%; in vented tail-gas, SO2 is ≤400 mg/m3, H2S is ≤5 mg/m3.

14. The method for deeply catalytically oxidizing the hydrogen sulfide to the element sulfur, as recited in claim 11, injecting air into a gas mixture at an entrance of the isothermal reactor according to a O2/H2S mole ratio required by the catalyst for selective oxidation and the gas mixture passes through a source gas; a sulfur recovery rate of an isothermal reaction is ≥95%; injecting air at an entrance of the adiabatic reactor according to the O2/H2S mole ratio required by the catalyst for burning tail-gas; in an adiabatic reaction a sulfur recovery rate is ≥90%, a conversion rate is ≥99%; in vented tail-gas, SO2 is ≤400 mg/m3, H2S is ≤5 mg/m3.

15. The method for deeply catalytically oxidizing the hydrogen sulfide to the element sulfur, as recited in claim 4, injecting air into a gas mixture at an entrance of the isothermal reactor according to a O2/H2S mole ratio required by the catalyst for selective oxidation and the gas mixture passes through a source gas; a sulfur recovery rate of an isothermal reaction is ≥95%; injecting air at an entrance of the adiabatic reactor according to a O2/H2S mole ratio required by the catalyst for burning tail-gas; in an adiabatic reaction a sulfur recovery rate is ≥90%, a conversion rate is ≥99%; in vented tail-gas, SO2 is ≤400 mg/m3, H2S is ≤5 mg/m3.

Referenced Cited
U.S. Patent Documents
7833935 November 16, 2010 Menini
9776133 October 3, 2017 Schoubye
20020121227 September 5, 2002 Hartmann
20030037705 February 27, 2003 Hartmann
20030194366 October 16, 2003 Srinivas
20090318285 December 24, 2009 Menini
20140155256 June 5, 2014 Becker
Foreign Patent Documents
102039137 May 2011 CN
Patent History
Patent number: 10166531
Type: Grant
Filed: Nov 4, 2015
Date of Patent: Jan 1, 2019
Patent Publication Number: 20170333880
Assignee: (Zibo, Shandong)
Inventor: Nan Yang (Zibo, Shandong)
Primary Examiner: Timothy C Vanoy
Application Number: 15/525,052
Classifications
Current U.S. Class: Of Iron (502/338)
International Classification: C01B 17/04 (20060101); B01D 53/86 (20060101); B01J 21/06 (20060101); B01J 23/745 (20060101); B01J 23/847 (20060101); B01J 35/00 (20060101); B01J 8/04 (20060101); C10K 1/00 (20060101); C10K 1/34 (20060101);